FINITE-DIFFERENCE-TIME-DOMAIN SIMULATION OF INSULATED
MONOPOLE IN BRAIN TUMOR HYPERTHERMIA TREATMENT
LEE CHIA WUI
A thesis submitted in fulfilment of the
requirements for the award of the degree of
Master of Engineering (Electrical)
Faculty of Electrical Engineering
Universiti Teknologi Malaysia
NOVEMBER 2015
iii
To education in science
iv
ACKNOWLEDGEMENT
The completion of this thesis has involved help from many peoples and
academician. In particular, I wish to express my sincere thanks to my supervisor Dr.
You Kok Yeow for his guidance. Without his guidance, this thesis would not have been
the same as presented. Special thanks to Librarian at University Teknologi of Malaysia
(UTM) for supplying the relevant literatures. My sincere appreciation also extends to all
my colleagues and others who have provided assistance. Last but not least, I am grateful
to my family members.
v
ABSTRACT
Hyperthermia treatment has been used to treat brain tumor diseases where
conventional surgical removal is invasive and poses threat to a patient. The
treatment technique is to apply microwave energy which transforms into heat on the
target tumour without overheating surrounding healthy tissue. The insulated
monopole has proven to be suitable as an applicator in hyperthermia treatment
whereby its thin slot form and small cross section area allows it to reach deep seated
brain tumour. Nowadays, simulation is used to evaluate insulated monopole design.
However, existing commercial simulators are difficult to learn and operate. In this
study, a simple and user friendly finite-difference-time-domain (FDTD) based
simulator written in MATLAB codes is developed for hyperthermia brain tumour
treatment. Using the developed simulator, electric field, specific-absorption-rate
(SAR) distribution and reflection coefficient of two designed insulated monopoles
have been studied. The first designed insulated monopole is a simple insulated
monopole with thin air gap. The second design is a multi-layer insulated monopole
used to treat large deep-seated brain tumour. The resulting electric field and SAR
distribution were compared and validated against analytical solutions and
commercial simulator’s results, respectively. The simulator’s result was found to be
more accurate with less reflection at the wave scatter boundary when complex
frequency shifted perfectly matched layer (CFS-PML) absorbing boundary condition
was used. And the optimal parameters of the absorbing boundary condition CFS-
PML in reducing computation cost were identified to be 10 layers with the degree of
polynomial, m = 4.
vi
ABSTRAK
Rawatan hipertermia telah digunakan untuk merawat tumor otak di mana
kaedah pembedahan konvensional adalah invasif dan membahayakan pesakit.
Rawatan ini menggunakan tenaga gelombang mikro untuk menjanakan tenaga haba
supaya memanaskan tumor tanpa memanaskan tisu yang sihat di sekelilingnya.
Ekakutub tertebat adalah peranti yang sesuai digunakan sebagai aplikator dalam
rawatan hipertermia. Ini disebabkan aplikator tersebut mempunyai keratan rentas
yang kecil dan terpencil di mana ia dapat mencapai kedudukan tumor yang terletak
dalam rongga otak. Kini, ekakutub tertebat biasanya direka dengan menggunakan
simulator. Tetapi, simulator komersial sedia ada sukar dioperasikan dan dipelajari.
Dalam kajian ini, simulator yang mudah dan mesra pengguna berdasarkan kaedah
perbezaan-terhingga-domain-masa (FDTD) telah dibina dengan menggunakan kod
MATLAB. Dua jenis ekakutub tertebat telah direka dan dikaji dengan simulator
tersebut dan prestasinya ditentukan berdasarkan taburan medan elektrik, taburan
kadar-penyerapan-tentu (SAR) dan pekali pantulan masing-masing. Bentuk
ekakutub pertama adalah ekakutub tertebat yang asas dengan lapisan udara di
tengah. Bentuk ekakutub yang kedua ialah ekakutub tertebat berbilang lapisan yang
diguna untuk merawat tumor otak yang besar dan letak dalam. Penyelesaian simulasi
seperti taburan medan elektrik dan SAR telah dibandingkan dengan penyelesaian
beranalisis dan kaedah unsur terhingga dan didapati lebih tepat disebabkan
pengunaan lapisan padanan sempurna teranjak frekuensi kompleks (CFS-PML) yang
mengurangkan pantulan di sempadan serakan gelombang. Parameter optimum yang
dikenal pasti untuk CFS-PML dalam mengurangkan kos pengiraan komputer adalah
10 lapisan pada darjah polynomial, m = 4.
vii
TABLE OF CONTENTS
CHAPTER TITLE PAGE
DECLARATION ii
DEDICATION iii
ACKNOWLEDGEMENT iv
ABSTRACT v
ABSTRAK vi
TABLE OF CONTENTS vii
LIST OF TABLES xi
LIST OF FIGURES xii
LIST OF ABBREVIATIONS xv
LIST OF SYMBOLS xvi
1 INTRODUCTION 1
1.1 Background of the Study 1
1.2 Problem Statements 3
1.3 Objectives of the Study 4
1.4 Scopes of the Study 4
1.5 Motivation of the Work 4
1.6 Thesis Outline 5
2 LITERATURE REVIEW 7
2.1 Introduction 7
viii
2.2 Theoretical Background of Insulated Monopole 8
2.2.1 Maxwell’s Equations 8
2.2.2 Analytical Analysis 9
2.2.2.1 Transmission Line Analysis 10
2.2.3 Numerical analysis 17
2.2.3.1 FDTD Mathematical Background 18
2.2.3.2 Finite Element Method (FEM) 20
2.2.3.3 Advantages and Disadvantages of FDTD
method 21
2.3 Insulated Monopole Applications 22
2.3.1 Hyperthermia Treatment 23
2.4 FDM and FDTD Analysis in Hyperthermia Treatment 26
2.4.1 Discretized Maxwell’s Equation 27
2.4.1.1 Singularity Handling in Cylindrical
Coordinate 29
2.4.2 Pennes’ Bioheat Equation 30
2.4.3 Material Properties of Brain Tissue 31
2.5 Absorbing Boundary Condition in FDTD 33
2.5.1 Berenger’s Perfectly Matched Layer (PML) 34
2.5.1.1 Numerical Reflection 36
2.5.1.2 Reflection from Limited Simulation Space
Boundary 37
2.5.2 Stretched Coordinate Perfectly Matched Layer
(SC PML) 37
2.5.3 Convolution Perfectly Matched Layer (CPML) 38
3 METHODOLOGY 40
3.1 Introduction 40
3.2 Assumption in Numerical Analysis 41
ix
3.3 FDTD and FDM Modeling 42
3.3.1 Rectangular Grid 42
3.3.1.1 Grid Discretization 43
3.3.2 Material Properties Definition 44
3.4 Boundary Conditions for FDTD Analysis 45
3.4.1 Convolution Perfectly Matched Layer (CPML)
Boundary 46
3.4.2 Perfect Electric Conductor (PEC) Boundary 47
3.5 FDTD Excitation Sources 47
3.6 FDTD Post-Processing 48
3.6.1 Time Domain Result 48
3.6.2 Fourier Transform to Frequency Domain 49
3.6.3 Input Impedance and Reflection Coefficient 50
3.7 Boundary Conditions for Bioheat Transfer 51
3.7.1 Boundary Conditions in FDM 52
3.8 Heat Source 53
3.9 GUI Features 53
4 SOFTWARE VALIDATION 56
4.1 Introduction 56
4.2 Insulated Monopole Model 56
4.3 FDTD Analysis Setup 57
4.4 Results Validation 61
4.4.1 Electric fields Validation 61
4.4.2 CPML absorption analysis 65
4.4.3 Input Impedance Validation 65
4.4.4 Temperature Contour Validation 66
4.5 CPML Optimization 67
4.6 Summary 69
x
5 BRAIN TUMOR HYPERTHERMIA TREATMENT WITH
MULTI-LAYERS INSULATED MONOPOLE 70
5.1 Introduction 70
5.2 Multi-Layers Insulated Monopole 70
5.3 FDTD analysis setup 72
5.4 Results 72
5.4.1 Reflection Coefficient 72
5.4.2 Electric field Distribution 73
5.4.3 Heat Distribution 74
5.5 Discussion 75
6 CONCLUSIONS AND FUTURE WORKS 77
6.1 Conclusions 77
6.2 Recommendation and Future Work 78
REFERENCES 79
Appendices A – C 84 -103
xi
LIST OF TABLES
FIGURE NO. TITLE PAGE
2.1 Advantages and disadvantages of FDTD over FEM 22
2.2 Dielectric properties of brain tissue at 2.45GHz
(Andreuccetti et al, 1996).
32
2.3 Thermal properties of brain tissue (Van de Kamer et
al.,2001).
32
2.4 Perfusion rate of brain tissue (Vaupel et al., 1989). 32
2.5 Blood properties (Elwasiff et al., 2006). 33
3.1 Boundary conditions in radial and axial direction 51
4.1 Parameters in the FDTD simulation. 57
5.1 Parameters (dimensions, dielectric and thermal properties)
defined in simulation
71
xii
LIST OF FIGURES
FIGURE NO. TITLE PAGE
1.1 3-D cross sectional view of thin monopole antenna
radiating wave to produce heat
2
2.1 Model of an insulated monopole antenna 8
2.2 Cylindrical coordinate of an insulated dipole. 10
2.3 Model of two layers insulated dipole antenna. 12
2.4 Position and direction of the field components within
acylindrical coordinate Yee’s cell.
19
2.5 Leapfrog scheme time marching sequence in FDTD
(Sullivan, 2000).
20
2.6 2D tetrahedral mesh used in FEM. Grid size is smaller
near to the sharp edges (Persson et al., 2004).
21
2.7 (a) Cross sectional view of multisection insulated
monopole (Iskander et al., 1989) (b) Capacitve loaded
multi-section insulated monopole. (Ahn et al., 2005)
25
2.8 Basic structure of two-slots coaxial antenna (Saito et al.,
2004)
26
2.9 Spatial grid points and field components for 2D
cylindrical problem
29
2.10 Integral path to evaluate Hz at ρ = 0 (Chen et al., 1996) 30
2.11 (a) Schematic of an infinite space for open-ended FDTD
simulation. (b) Schematic of truncated space to absorb all
outgoing waves.
34
2.12 An incident wave hits PML interface and attenuated inside
PML, reducing its amplitude. When it hits the end PEC
boundary, wave is reflected and attenuated again
36
xiii
3.1 Operational framework of studied simulator. 41
3.2 Color surface plot of material constant ga of an insulated
monopole
45
3.3 Boundary conditions defined for hyperthermia treatment
analysis
46
3.4 Developed simulator’s GUI components 55
4.1 Geometry of insulated monopole. 57
4.2 Dialog box of “Change geometry details” and inputs
entered
58
4.3 Dialog box of “Change antenna parameters” and inputs
entered
59
4.4 Dialog box of “Frequency domain Simulation” and input
entered
60
4.5 Dialog box of “Bioheat Simulation” and inputs entered 61
4.6 Six cross sections where electric fields are compared. 62
4.7 Electric field near insulated monopole normalized to
maximum at cross section parallel to z-axis. (a) Eρ and (b)
Ez
63
4.8 Electric field near insulated monopole normalized to
maximum at cross section parallel to ρ-axis. (a) Eρ and (b)
Ez
64
4.9 Comparison of Simulator’s result with analytical solution
and FEM method.
66
4.10 Comparison of calculated temperature contour line for 43̊
C using FDTD and COMSOL simulator.
67
4.11 Experimental reflection factor as a function of theoretical
reflection factor.
68
5.1 Cross-sectional view of multi-layers insulated monopole 71
5.2 Comparison of reflection coefficient from studied
simulator and COMSOL Multiphysics.
73
5.3 Logarithm Enorm field distribution in brain tumor at 2.45
GHz. (a) Studied FDTD-based simulator (b) COMSOL
Multiphysics.
74
xiv
5.4 Comparison of temperature contour at 43̊ C with
COMSOL simulation.
75
xv
LIST OF ABBREVIATIONS
ABC - Absorbing Boundary Condition
CFS - Complex Frequency-Shifted
CPML - Convolutional Perfectly Matched Layer
EM - Electromagnetic
FEM - Finite Element Method
FDM - Finite Difference Method
FDTD - Finite Difference Time Domain
MoM - Method of Moments
PDE - Partial Differential Equation
PEC - Perfect Electric Conductor
PML - Perfectly Matched Layer
SAR - Specific Absorption Rate
TEM - Transverse Electromagnetic
TM - Transverse Magnetic
UPML - Uniaxial Perfectly Matched Layer
xvi
LIST OF SYMBOLS
ε - permittivity
σ - conductivity
E - electric field
H - magnetic field
B - magnetic flux density
D - electric flux density
J - electric current density
ρ - electric charge density
k - complex wavenumber
Z - characteristic impedance
q - electric charge per unit length
p - density
λ - wavelength
Г - reflection coefficient
Cp - Heat Capacity
K - Thermal conductivity
ω - volumetric perfusion rate
T - Temperature
xvii
LIST OF APPENDICES
APPENDIX TITLE PAGE
A Frequency Response of Differentiated Gaussian pulse 84
B Matlab code 86
B1 fdtd_cpml.m 86
B2 generate_mesh.m 93
B3 bioheat.m 96
B4 pde_bioheat.m 97
B5 calc_impedance.m 99
C FEM Analysis setup in COMSOL Multiphysics 100
CHAPTER 1
INTRODUCTION
1.1 Background of the Study
In medical field, hyperthermia treatment has been seen as a better alternative
treatment to tumor disease (Moroz et al., 2002). Conventional practicing treatment such
as surgical operation, chemotherapy and radiotherapy leave side effects to patient, as it
is not localized on the tumor and rather toxic in the process. Hyperthermia treatment on
the other hand is the opposite, where thin needle shape of insulated monopole antenna is
penetrated into the target tumor tissue through skin and electromagnetic wave is
radiated to produce heat as shown in Figure 1.1. Eventually, the surrounding
temperature of tumor tissue cell increased to the therapeutic temperature between 42
and 45 °C for the purpose of destroying cancer tumor cells (Guojun et al., 2010).
For hygienic purpose, near lossless dielectric material is used to cover the
conductor of the bare monopole antenna. In the process of the treatment, temperature
near to the antenna can reach 100 C. Air gap is introduced between the conductor and
the tumor cells to protect the antenna.
2
Figure 1.1: 3-D cross sectional view of thin monopole antenna radiating wave to
produce heat.
In hyperthermia study, the primary interest is the near field close to the antenna
where most of the heating takes place. Different design configuration of the monopole
and Radio frequency (RF) or thermodynamic parameters will produce different heat
distribution. Due to complexity of configuration of monopole antenna (multilayer
insulated monopole antenna), researchers nowadays use simulator to calculate the heat
distribution in preliminary design stage of antenna. In this study, finite difference time
domain (FDTD) is employed to study the electromagnetic field and specific absorption
rate (SAR) distribution produced by the insulated monopole. FDTD has the advantages
of being simple to implement and capable of wideband analysis compare to other
method such as finite element method (FEM) and Method of Moment (MoM). Detail
description of FDTD will be available in Chapter 2. On the other hand, finite difference
method (FDM) is subsequently used to calculate the heat distribution using SAR
distribution as heat source.
The research work is divided into two parts. The first part is to validate the
computational result by studied simulator with the calculated result from the analytical
Antenna
Body
tissue
3
method and commercial software. The model used in the validation is a simple one
layer insulated monopole and the validated result includes electric field distribution,
input impedance, and heat distribution which are the essential parameters in brain tumor
hyperthermia treatment (Ahn et al., 2005). In the second part, the studied simulator is
used to design multi-layers insulated monopole and calculated performances are
validated using commercial software, so-called COMSOL Multiphysics.
1.2 Problem Statements
Recently, most of the commercial simulators are catered for multidisciplinary
purpose due to competitive market. Thus, this kind of simulator has a lot of parameters
or constant values are required to be properly defined before performing the simulation.
In this study, a simple, accurate and user friendly graphical-user-interface (GUI) FDTD-
based simulator particularly for insulated monopole will be developed for hyperthermia
brain tumor treatment.
Brain tumors are among the most difficult forms of cancer to treat as brain
tumor can be large and deep seated in brain cavity. The insulated monopole is an
appropriate selection to treat brain tumor with hyperthermia technique since it is long,
thin and small in cross sectional area to reach the targeted tumor. Furthermore, the
monopole antenna’s return loss has to be low to achieve the maximum energy transfer
to the brain tumor from the monopole.
Besides, deviation between experimental result and simulation result in open-
ended FDTD simulations caused by reflected outgoing electromagnetic waves from
computational domain’s boundary is also improved in this study.
4
1.3 Objectives of the Study
Create FDTD-based GUI simulator using MATLAB to solve the insulated
monopole problems. The 2-D studied simulator is particularly used to simulate insulated
monopole in brain tumor for hyperthermia application.
On the other hand, the sub-objective of this study is to identify the optimal
parameters of the absorbing boundary condition-CPML used in FDTD in order to
improve the accuracy of the simulation.
1.4 Scopes of the Study
Scope of this study can be broken down as:
i. To review analytical method, FEM and FDTD methods in solving insulated
monopole’s problem and identify their advantages and disadvantages.
ii. To validate the accuracy of studied simulator and improve it by reducing the
reflection from the boundary.
iii. To determine electric field and heat distribution radiated by insulated monopole
in brain tumor hyperthermia application using studied FDTD-based simulator.
iv. To use parameters from available published ex-vivo experimental work (Ahn et
al., 2005) in simulation work. Experimental work will not be part of the study.
1.5 Motivation of the Work
Recently, hyperthermia treatment has been proven to be capable and reliable to
treat cancer tumor (Sterzer, 2002). Therefore, this project is held to contribute in
respective field especially in brain tumor treatment. In fact, the hyperthermia treatment
5
performance can be referred to the numerical simulation result without actual build of
the treatment system.
However, electromagnetic field and heat distribution simulations involve both
complex mathematics and numerical computation that are difficult to comprehend and
master. Through this work, better understanding of the underlying can be gained and
eventually improves simulation accuracy. Improving accuracy in simulation will
decrease the cost in designing applicator for hyperthermia treatment and deliver better
guarantee of its use.
1.6 Thesis Outline
The thesis is divided into 6 chapters. Chapter 2 reviews history and theoretical
background of analytical and numerical method on insulated monopole. Advantages
and disadvantages between FDTD and FEM are also compared. Next, different designs
of insulated monopoles used as applicator in hyperthermia treatment are presented.
Finally, brief theoretical background of absorbing boundary condition used to absorb
scattering electromagnetic waves at the boundary is outlined.
Chapter 3 describes the methodology used to develop the FDTD-based
simulator. MATLAB codes on source excitation, post processing, SAR and heat
distribution calculations are presented. Assumption and boundary conditions used are
mentioned.
Chapter 4 discusses the validation results of developed simulator with analytical
method and commercial software. The optimized parameters for absorbing boundary
conditions to reduce computation resource are also addressed.
Chapter 5 presents the application of developed simulator on multi-layer
insulated monopole used in brain tumor hyperthermia treatment. The validation of
6
simulated result with commercial simulator, namely COMSOL Multipyhsics 4.2, is also
presented.
Chapter 6 concludes this project and presented future work recommendation to
further reduce the differences between simulation result and experimental result in brain
tumor hyperthermia.
79
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